Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
CA 02753510 2016-07-25
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INTEGRATED ELECTRIC VANE OIL PUMP
CROSS-REFERENCE TO RELATED APPLICATIONS
FIELD
[0001] The present disclosure generally relates to an electric motor
driven pump.
[0002] More particularly, a submersible integrated electric vane oil pump
is described.
BACKGROUND
[0003] This section provides background information related to the
present disclosure which is not necessarily prior art.
[0004] A number of electric pumps have been disclosed combining an
electric motor and a vane pump. For example, U.S. Patent No. 6,499,964
describes an electric motor and a vane pump that are usable separately or in
combination with one another. While this concept may provide the desired
pumping function, redundancies exist, possibly negatively affecting the cost,
size
and weight of the fluid pump.
[0005] In addition, U.S. Patent No. 4,407,641 describes an electrically
driven vane pump. The rotor of the electric motor and the rotor of the vane
pump
are integrated with each other. However, the disclosed pump arrangement
includes multiple casings and occupies a relatively large volume of space.
Accordingly, a need in the art exists for an improved integrated electric vane
oil
pump.
SUMMARY
[0006] This
section provides a general summary of the disclosure,
and is not a comprehensive disclosure of its full scope or all of its
features.
[0007] An electric vane
pump includes a first cover plate having a
substantially planar first pump surface and a second cover plate coupled to
the
first cover plate defining a substantially planar second pump surface spaced
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apart from and extending substantially parallel to the first pump surface.
A
plurality of permanent magnets are fixed to a rotor. A plurality of radially
moveable vanes are fixed for rotation with the rotor. Each vane is positioned
between the first and second pump surfaces and has a first end slidably
engaging a center vane support. An electric motor stator is positioned between
the first and second cover plates and circumscribes the rotor. A resilient
member biases each of the vanes into engagement with the center vane
support.
[0008] In
another arrangement, an electric vane pump includes first
and second shells having substantially planar first and second pump surfaces,
respectively. The first and second pump surfaces are spaced apart from and
extend substantially parallel to one another. The electric vane pump also
includes a center vane support, a rotor and a plurality of radially moveable
vanes
fixed for rotation with the rotor. Each vane is positioned between the first
and
second pump surfaces and has an end slidably engaging the center vane
support. A shaft including spaced apart shoulders engages each of the first
and
second shells to define a predetermined spacing between the first and second
pump surfaces. An electric motor stator is positioned between the first and
second shells. A plurality of permanent magnets are fixed for rotation with
the
rotor and positioned proximate the stator.
[0009]
Further areas of applicability will become apparent from the
description provided herein. The description and specific examples in this
summary are intended for purposes of illustration only and are not intended to
limit the scope of the present disclosure.
DRAWINGS
[0010]
The drawings described herein are for illustrative purposes only
of selected embodiments and not all possible implementations, and are not
intended to limit the scope of the present disclosure.
[0011]
Figure 1 is a perspective view of an electric vane pump
constructed in accordance with the teachings of the present disclosure;
[0012]
Figure 2 is a fragmentary perspective view of the electric vane
pump;
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[0013] Figure 3 is a cross-sectional view of the electric vane
pump;
[0014]
Figure 4 is a perspective view of an alternate electric vane
pump;
[0015]
Figure 5 is another perspective of the alternate electric vane
pump;
[0016]
Figure 6 is a cross-sectional view of the alternate electric vane
pump;
[0017]
Figure 7 is a fragmentary perspective view of the alternate
electric vane pump depicted in Figures 4-6;
[0018] Figure 8 is
a perspective view of another alternate electric vane
pump;
[0019]
Figure 9 is a fragmentary perspective view of the electric vane
pump depicted in Figure 8;
[0020]
Figure 10 is another perspective view of the pump depicted in
Figures 8 and 9; and
[0021]
Figures 11 and 12 depict a schematic for generating an
alternate center vane support surface.
[0022]
Corresponding reference numerals indicate corresponding parts
throughout the several views of the drawings.
DETAILED DESCRIPTION
[0023]
Example embodiments will now be described more fully with
reference to the accompanying drawings.
[0024]
Figures 1-3 depict an integrated electric vane oil pump
identified at reference numeral 10. Pump 10 includes a housing 12 having a
first
shell 14 and a second shell 16. Each of first shell 14 and second shell 16 may
be formed as aluminum die castings. A stator 18 is sandwiched between first
shell 14 and second shell 16. First shell 14, second shell 16 and stator 18
are
fixed to one another along the perimeter of pump 10. Any number of fastening
methods may be employed including screwing, crimping, clamping, riveting,
welding, adhesive bonding or the like.
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[0025]
Electric vane oil pump 10 includes a shaft 20, a center vane
support 22, a rotor assembly 24 and a plurality of vanes 26 in cooperation
with
one another to define a vane pump. Shaft 20 is a substantially cylindrically
shaped member having a longitudinal axis 28. Rotor assembly 24 is supported
for rotation within recesses 30, 32 formed within first shell 14 and second
shell
16, respectively. Recess 30 is at least partially defined by a substantially
planar
first pump surface 34 and a circumferentially extending wall 36. In similar
fashion, recess 32 is defined by a second pump surface 38 and a
circumferentially extending wall 40. Walls 36 and 40 are aligned with one
another along an axis of rotation 42 about which rotor assembly 24 rotates.
[0026]
Rotor assembly 24 includes a rotor 43 including plurality of
radially extending blind slots 44 each in receipt of a radially moveable vane
26.
Slots 44 are configured to fix vanes 26 for rotation with rotor 43 while
allowing
each vane 26 to independently radially move during rotation of rotor assembly
24. Each vane 26 includes a first end 46 positioned within one of slots 44 and
a
second opposite end 48 in contact with a substantially cylindrical outer
surface
50 of center vane support 22. A pair of resilient retaining clips 52, 54 are
positioned within circumferential grooves 56, 58 formed on opposite sides of
rotor 43. Each retaining clip 52, 54 is a split ring sized to engage first
ends 46 of
vanes 26 to maintain second ends 48 in contact with surface 50. Due to the
eccentric arrangement between center vane support 22 and rotor assembly 24,
pump 10 is operable to draw fluid from a low pressure reservoir through an
inlet
port 60 while pressurized fluid exits pump 10 at an outlet port 62. Inlet port
60
extends through second shell 16. Outlet port 62 also extends through second
shell 16.
[0027] A
first fastener 64 extends through a counterbore 65 form in
first shell 14 to fix a first end 66 of shaft 20 to first shell 14. A reduced
diameter
portion 68 is formed at first end 66 and placed in communication with a first
recess 70 formed in first shell 14 to accurately position shaft 20. First
fastener
64 draws a first shoulder 72 of shaft 20 into contact with an offset face 74
formed
on first shell 14.
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[0028] In
similar fashion, a second fastener 76 extends through a
counterbore 77 formed in second shell 16 to fix a second end 78 of shaft 20 to
second shell 16. A stepped reduced diameter portion 80 is accurately
positioned
within a recess 82 formed in second shell 16. A second shoulder 84 is secured
against an offset face 86 formed on second shell 16. The distance between
first
shoulder 72 and second shoulder 84 is accurately controlled to define a
running
clearance between rotor assembly 24, first shell 14 and second shell 16.
Furthermore, fasteners 64, 76 restrict first shell 14 and second shell 16 from
moving away from rotor assembly 24 while fluid forces are generated during
pumping. Proper pump function is thereby maintained.
[0029]
Shaft 20 also defines a gap 88 between an end face 90 of first
shell 14 and an end face 92 of second shell 16. A plurality of magnets 94 are
fixed for rotation with rotor 43. Magnets 94 are arranged in alternating
polarity
about the circumference of rotor 43 and positioned within gap 88.
[0030] Stator 18
includes a plurality of plates 96 encompassed by
windings 98. Stator 18 includes an outer cylindrical surface 100 and an inner
cylindrical surface 102. First shell 14 includes a pocket 104 in receipt of a
portion of stator 18. Pocket 104 is defined by an inner cylindrical wall 106,
an
outer cylindrical wall 108 and an end wall 110 interconnecting wall 106 and
wall
108. Outer cylindrical wall 108 is sized to closely fit outer cylindrical
surface 100
of stator 18. A gap exists between stator 18 and inner cylindrical wall 106 as
well as between end wall 110 and stator 18. A flexible sealing compound or
adhesive may be used to fill the gaps and couple stator 18 to first shell 14
while
allowing relative movement therebetween. Second shell 16 includes a similar
pocket 112 defined by an inner cylindrical wall 114, an outer cylindrical wall
116
and an end wall 118. The fit between the various surfaces of stator 18 and
second shell 16 are similar to those previously described with relation to
first
shell 14.
[0031]
Magnets 94 are positioned in close proximity to but clear of first
shell 14, second shell 16 and inner cylindrical surface 102 of stator 18. It
should
be appreciated that the windings 98 of stator 18 need not be positioned within
a
protective case and, therefore, may be positioned in very close proximity to
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magnets 94. It should be appreciated that the efficiency of the electric motor
increases as the gap between magnets 94 and windings 98 is decreased. To
maximize motor efficiency, it is contemplated that the distance between
permanent magnets 94 and a current carrying portion of stator 18 ranges from
about 0.5 mm to 0.8 mm. Furthermore, windings 98 may be placed in direct
contact with a fluid to be pumped if pump 10 is fully submerged.
This
arrangement increases heat transfer away from stator 18 by contact with the
fluid. Pump 10 is also operable in a partially submerged or in a non-submerged
mode as well.
[0032] Pump 10 may
be optionally equipped with a high pressure
passage 120 interconnecting outlet port 62 and pressure chambers 122, 124
formed in first shell 14 and second shell 16, respectively.
During pump
operation, pressurized fluid flows from outlet port 62 through passage 120 to
pressure chambers 122, 124 to apply a force on first ends 46 of vanes 26. The
pressurized fluid further drives second ends 48 of vanes 26 into contact with
outer surface 50. The forces applied by the pressurized fluid and retaining
clips
52, 54 counteract fluid pressure and centripetal acceleration forces
attempting to
move vanes 26 radially outwardly.
[0033] In
operation, current is passed through windings 98 to generate
a magnetic field. Permanent magnets 94 are urged to move thereby causing
rotor 43 to rotate. As vanes 26 rotate, fluid pumping occurs. As pumping
continues, first fastener 64 and second fastener 76 restrict first shell 14
and
second shell 16 from spacing apart from one another and changing the distance
between first pump surface 34 and second pump surface 38. Furthermore,
retaining clips 52, 54 maintain a biased engagement between vanes 26 and
surface 50 to assure proper pump function at various pump speeds.
[0034]
Figures 4-8 depict an alternate pump identified at reference
numeral 130. Pump 130 is also an integrated electric vane oil pump that may be
fully submersible within a fluid to be pumped. Integrated electric vane oil
pump
130 includes a housing 132 having a first cover plate 134, a second cover
plate
136 and an intermediate ring 138. Each of the first and second cover plates
134,
136 may be formed as aluminum die castings. Intermediate ring 138 is
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sandwiched between first cover plate 134 and second cover plate 136 to
compensate for the coefficient of thermal expansion of housing 132 possibly
being different than the components within housing 132. To accomplish this
goal, intermediate ring 138 is preferably constructed from a material having a
coefficient of thermal expansion substantially less than that of aluminum. For
example, intermediate ring 138 may be constructed from a powdered metal
material. First cover plate 134, second cover plate 136 and intermediate ring
138 are fixed to one another along the perimeter of pump 130 by a plurality of
fasteners 140. It should be appreciated that any number of other fastening
methods may be employed including crimping, clamping, riveting, welding,
adhesive bonding or the like.
[0035]
Pump 130 includes a rotor assembly 142 acting in cooperation
with an integral, monolithic, shaft and center vane support 144. A stator 146
surrounds rotor assembly 142. Combination shaft and center vane support 144
includes a substantially cylindrical body 148 having axially aligned first and
second trunnions 150, 152. At the intersection between body 148 and first
trunnion 150 is a first seat 154. A second seat 156 is formed at the
intersection
between body 148 and second trunnion 152. Seats 154, 156 engage a first
pump face 158 formed on first cover plate 134 and a second pump face 160
formed on second cover plate 136, respectively. Each of trunnions 150, 152
includes a groove in receipt of a retaining ring 162. Retaining rings 162
restrict
first cover plate 134 from moving relative to second cover plate 136 during
pump
operation.
[0036] An
inlet 166 is formed in second cover plate 136 to allow low
pressure fluid to be drawn into communication with rotor assembly 142. An
outlet 168 is also formed in second cover plate 136 for providing a passageway
for pressurized fluid exiting pump 130. A plurality of fins 170 are integrally
formed on second cover plate 136 for transferring heat from pump 130 to the
fluid to be pumped. A plurality of radially extending vents 171 are formed
within
intermediate ring 138 to allow fluid to pass through housing 132 into
communication with stator 146 to further assist in transferring heat from pump
130 to the surrounding fluid.
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[0037]
Rotor assembly 142 includes a plurality of vanes 172 fixed for
rotation with but radially moveable relative to a rotor 174. One end of vanes
172
is in contact with a substantially cylindrical outer surface of body 148.
First and
second elastomeric members 178, 180 circumscribe the opposite ends of vanes
172 to biasedly engage the vanes with combination shaft and center vane
support 144. Elastomeric members 178, 180, may be constructed as o-rings
having circular cross sections. Other geometrical shapes may also be used. A
high pressure passage 181 interconnects outlet 168 with a first cavity 182
formed between rotor 174 and first cover plate 134 as well as a second cavity
183 formed between rotor 174 and second cover plate 136. Pressurized fluid
within cavities 182, 183 urges vanes 172 toward body 148.
[0038]
Rotor 174 includes an inner pair of flanges 184, 186 axially
extending from opposite ends of a body portion 188. First cover plate 134 and
second cover plate 136 also include corresponding axially extending flanges
190, 192 for limiting axial translation of rotor 174. Rotor 174 also includes
first
and second outer flanges 196, 198. First outer flange 196 includes an inner
cylindrical surface 200 overlapping an outer cylindrical surface 202 formed on
first cover plate 134. Similarly, a second cylindrical inner surface 204 of
second
outer flange 198 is positioned adjacent to an outer cylindrical surface 206
formed
on second cover plate 136. Outer cylindrical surfaces 206 and 202 are aligned
with one another along an axis 210.
[0039]
Due to the arrangement previously discussed, rotor 174 is
guided to rotate about axis 210. Body 148 defines a longitudinal axis 212
extending substantially parallel to and offset from axis 210. As previously
discussed, this eccentric arrangement provides the pumping action when rotor
assembly 142 is rotated. Rotor assembly 142 also includes a plurality of
permanent magnets 214 spaced apart from one another in alternating polarity
about the circumference of rotor 174. Permanent magnets 214 are placed in
close proximity to stator 146.
[0040] Figures 8-10
depict another alternate integrated electric vane oil
pump identified at reference numeral 250. Pump 250 is substantially similar to
pumps 10 and 130 previously described. Accordingly, similar elements will be
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identified with like reference numerals including an "a" suffix. In
particular,
pump 250 combines the housing features of pump 130, now identified as first
cover plate 134a, second cover plate 136a and intermediate ring 138a with the
internal pump features of pump 10, now depicted as stator 18a, rotor assembly
24a, shaft 20a, center vane support 22a and fasteners 64a and 76a. It should
be appreciated that while pump 250 is shown to be equipped with retaining
clips
52a, 54a, elastomeric members 178, 180 may be used in their place in either
pump 250 or pump 10. Similarly, the dual fastener arrangement 64, 76 and 64a,
76a may be replaced with a pin and retaining ring arrangement as used by pump
130.
[0041]
Pump 250 includes second cover plate 136a having an axially
extending boss 252 defining outlet 168a. A plurality of pockets 254 are also
formed in second cover plate 136a to reduce the weight of pump 250. Similar
pockets 256 are formed within first cover plate 134a. Another boss 258 is
formed on first cover plate 134a and defines inlet 166a.
[0042]
Figures 11 and 12 depict a center vane support 300 having an
outer surface 302 defined by a special profile to minimize gaps between vanes
26 and center vane support 300. It should be appreciated that each of the
embodiments previously described may be modified to include the special
profile
depicted in Figures 11 and 12, if desired. As such, the outer surface of
center
vane support 22 or the outer surface of shaft and center vane support 144 may
be manufactured to no longer define a circular cylindrical surface but include
the
shape of surface 302. Through the use of shaped surface 302, first end 46 of
each vane 26 radially translates less during operation than when a circular
cylindrically shaped vane contact surface is formed on the center vane
support.
Accordingly, elastomeric elements such as retaining clips 52, 54 do not need
to
account for relatively large differences in the radial position of first ends
46 of
vanes 26. A more consistent contact pressure between second end 48 of each
vane 26 and profile 302 may result. The shape of profile 302 is defined by the
following equations such that the equations may be solved to plot profile 302
as
(R', B).
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Equations:
(r + = [e2 Rv2 ¨2 * Rv * e * cos(90 ¨ Phi)]
r = [e2 + Rv2 ¨ 2 *Rv * e * cos(90¨ PhO] 5 ¨L (1)
[Rv * cos(Phi)]
COS (psi) =
R + L
sin (psi)
[Rv * sin(Phi) ¨ e]
=
R + L
psi = tan-1 [Rv * sin(Phi)¨ e]
[Rv* cos(Phi)] (2)
Pi
a = + psi (3)
rr 2 = [r2 e2 2 * r *e * cos(a)]
n
rr = r2 +e2 ¨z*r*e* cos(a)] 5 (4)
* sin(psi) + e]
B = tan-1 [r
[r * cos(psi)] (5)
R' = rr ¨ rv (6)
where:
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r = slide center to rotor OD
L = vane length
e = eccentricity
Rv = vane ring ID radius
Phi = angle of vane ID radius relative to rotor center
Psi = angle of vane relative to slide center
a = angle from eccentricity line to r+L line
B= angle relative to rotor center to rr line
rr = calculated rotor profile relative to rotor center and extending to vane
radius
center point
rv = vane radius
R' = corrected rotor profile relative to rotor center considering the vane
radius
(i.e. inner offset of profile by rv)
pi = constant = 3.14
[0043] To assure
proper pump operation, the component including
profile 302 is rotated to a predetermined position relative to line y passing
through the center of rotor 24 and the center of center vane support 300. Any
number of mechanical devices including a dowel, a key or some other
asymmetric feature may be incorporated to assure proper orientation of profile
302.
[0044]
The foregoing description of the embodiments has been
provided for purposes of illustration and description. It is not intended to
be
exhaustive or to limit the invention.
Individual elements or features of a
particular embodiment are generally not limited to that particular embodiment,
but, where applicable, are interchangeable and can be used in a selected
embodiment, even if not specifically shown or described. The same may also be
varied in many ways. Such variations are not to be regarded as a departure
from
the invention, and all such modifications are intended to be included within
the
scope of the invention.
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